Method for nondestructive/noncontact detection and quantification of alpha case on a surface of a workpiece made of titanium or a titanium-based alloy

ABSTRACT

A method for nondestructive/noncontact detection of alpha case on a surface of a workpiece made of titanium or a titanium-based alloy. Infrared radiation is reflected off of a selected portion of the workpiece surface and sensed by a detector which may comprise a scanning infrared radiometer, an infrared camera, or a spot radiometer. The presence of any alpha case in the selected portion of the workpiece surface is detected by comparing the intensity of the reflected infrared radiation to a predetermined intensity known to be indicative of the absence of alpha case. An image of the reflected infrared radiation may be created and the step of detecting the presence of alpha case may include the step of comparing the intensity of the reflected infrared radiation within the image to the predetermined intensity. According to a preferred embodiment, a target may be disposed between the source of the infrared radiation and the workpiece surface so as to create a predetermined pattern within the image. In this embodiment, the step of detecting may further include the step of comparing the clarity of the predetermined pattern with the image created from the reflected infrared radiation from the selected portion of the workpiece surface to the clarity of the predetermined pattern within an inspection standard image known to be indicative of the absence of alpha case.

BACKGROUND OF THE INVENTION

1.0 Field Of The Invention

The present invention relates generally to a method for nondestructive/noncontact detection and quantification of alpha case on a surface of a workpiece made of titanium or a titanium-based alloy, and more particularly to a method for nondestructive/noncontact detection and quantification of alpha case on surfaces of titanium or titanium-based alloy components used in gas turbine engines.

2.0 Related Art

Titanium-based alloys are used in the manufacture of a wide variety of gas turbine engine components due to the relatively high mechanical strength and low density of titanium-based alloys and the ability of titanium-based alloys to withstand the moderately high temperatures which may be encountered in certain portions of gas turbine engines, while maintaining their mechanical strength. Such applications for the use of titanium-based alloys include the manufacture of fan and compressor casings and exhaust ducts in gas turbine engines. Components made of a titanium-based alloy are typically heat treated in order to enhance the mechanical properties of the alloy. However, during the heat treat process alpha case is typically formed on one or more surfaces of the titanium-based alloy components. Alpha case may be characterized as an oxygen and nitrogen enriched alpha-stabilized surface which results from high temperature exposure and which may extend up to several mils in depth from the surface of the component. Alpha case may also be formed during operation of the gas turbine engine due to a local over-temperature condition of the titanium-based alloy component. Alpha case may also be formed, as a result of high temperature exposure, on the surface of titanium components. Alpha case areas on the surface of titanium or titanium-based alloy components are very brittle, as compared to non-alpha-case areas, and are susceptible to cracking under stress such as the stresses imposed during operation of a gas turbine engine. Any crack initiating in the relatively thin alpha case layer may then propagate through the component to an extent which may lead to component failure.

Conventional methods for the detection of alpha case include the destructive testing of sample coupons, or the use of chemical etching processes followed by the application of intrusive dyes. Although the use of destructive testing has been somewhat successful as applied to newly produced components, it is relatively expensive and may not be used to detect alpha case created by the field operation of components. Additionally, the use of coupons introduces inaccuracies due to their inability to exactly duplicate the heating and cooling history experienced by the component during the manufacturing process since the coupons heat and cool at much faster rates than the actual component, particularly with respect to relatively large components The use of chemical etching and intrusive dyes has been less successful and additionally, the chemicals and dyes employed must be carefully controlled so as to avoid environmental problems.

Several conventional methods are known which employ infrared radiation for detecting either surface flaws or defects, such as microcracks, or subsurface defects such as voids and inclusions. These known methods require heating the surface to be inspected and are based on the principle that the infrared radiation emitted by the area corresponding to the defect or flaw will be different than that emitted from the surrounding area of the component, due to the difference in temperature of the area including the flaw or defect as compared to the temperature of the surrounding area. Methods of this type are subject to non-uniform heating of the component, particularly in the case of a relatively large component, which may mask the presence of a flaw or defect, or give a false indication of a flaw or defect. The inventors are unaware of any such known method being utilized to detect alpha case on the surface of titanium or titanium-based alloy components. Furthermore, the method of the present invention differs fundamentally from the foregoing infrared detection methods since the method of the present invention does not require heating the component to be inspected and utilizes reflected, not emitted, infrared radiation to detect the presence of alpha case.

At the time of the present invention, a need existed for a reliable, cost effective, nondestructive and environmentally safe method for detecting the presence of alpha case on the surface of titanium and titanium-based alloy components such as those used in gas turbine engines.

SUMMARY OF THE INVENTION

Accordingly, the present invention is directed to a method for nondestructive/noncontact detection of alpha case on the surface of a workpiece made of a material selected from a group consisting of titanium and titanium-based alloys. According to a preferred embodiment of the present invention, the method comprises the steps of: reflecting infrared radiation off of a selected portion of the surface of the workpiece; sensing the reflected infrared radiation with a detector; and detecting the presence of any alpha case in the selected portion of the surface of the workpiece. The step of detecting comprises the step of comparing the intensity of the reflected infrared radiation from the selected portion of the surface of the workpiece to a predetermined intensity known to be indicative of the absence of alpha case, wherein the presence of alpha case causes a reduction in intensity of the reflected infrared radiation from the selected portion of the surface of the workpiece relative to that of the predetermined intensity.

According to other preferred embodiments, the foregoing method steps may be further defined and the method may include additional steps as follows. The method may further include the step of creating an image of the reflected infrared radiation and the step of comparing the intensity of the reflected infrared radiation may comprise the step of comparing the intensity of the reflected infrared radiation within the image to the predetermined intensity. The step of reflecting the infrared radiation may include the steps of positioning a controlled source of the infrared radiation spaced apart from the surface of the workpiece and directing the infrared radiation emitted by the source onto the selected portion of the workpiece surface. The method may further include the step of disposing a target between the source of the infrared radiation and the workpiece surface so as to create a predetermined pattern within the image of the reflected infrared radiation. In this embodiment, the step of detecting further comprises the step of comparing the clarity of the predetermined pattern within the image of the reflected infrared radiation from the selected portion of the workpiece surface to the rarity of the predetermined pattern within an inspection standard image known to be indicative of an absence of alpha case.

The step of comparing the intensity of the image of the reflected radiation to the predetermined intensity, known to be indicative of the absence of alpha case, may comprise the steps of generating a graph of the intensity of the image of the reflected radiation versus distance along the workpiece within the image and comparing peak values of intensity shown in the graph to the predetermined intensity indicating an absence of alpha case.

The detector is selected from a group consisting of a scanning infrared radiometer, a spot infrared radiometer and an infrared camera, and the method may further include the step of operating the detector in a predetermined wavelength band, preferably ranging from about 3 microns to about 5 microns.

The method may further include the step of fixturing the source and the detector of the infrared radiation so that the detector is substantially aligned with the optical path of the infrared radiation reflected off of the selected portion of the surface of the workpiece. The image of the reflected radiation may be displayed on a video display monitor, and the predetermined pattern may comprise a plurality of spaced, generally rectangular shapes.

BRIEF DESCRIPTION OF THE DRAWINGS

The method steps of the present invention will become more apparent from the following detailed description of the preferred embodiments when taken in conjunction with the accompanying drawings wherein:

FIG. 1 is a combined schematic and block diagram of an inspection system which may be used for nondestructive/noncontact detection and quantification of alpha case in accordance with a first embodiment of the method of the present invention;

FIG. 2 is a graph comparing the reflectance of a non-alpha-case titanium-based alloy to the reflectance of alpha case, as a function of wavelength;

FIG. 3 is a combined schematic and block diagram of a system which may be used for nondestructive/noncontact detection and quantification of alpha case in accordance with a second, preferred embodiment of the method of the present invention;

FIG. 4 is a view taken along line 4-4 in FIG. 3 illustrating a target and target housing;

FIG. 5A is a photograph of an image created from infrared radiation reflected from a non-alpha-case surface of a coupon made of titanium 6-4;

FIG. 5B is a photograph of an image created from infrared radiation reflected off of a coupon surface having moderate alpha case, with the coupon being made of titanium 6-4;

FIG. 5C is a photograph of an image created from infrared radiation reflected off of a coupon surface having heavy alpha case,, with the coupon being made of titanium 6-4;

FIG. 6 is a graph of the intensity of each of the images shown in FIGS. 5A-5C versus distance within the corresponding image.

DETAILED DESCRIPTION

Referring now to the drawings, FIG. 1 is a combined schematic and block diagram illustrating an inspection system, indicated generally at 10, which may be used for the nondestructive/noncontact detection of alpha case on a surface 12 of a workpiece, or component 14 made of titanium or a titanium-based alloy, in accordance with a first embodiment of a method of the present invention. Examples of titanium-based alloys which may be used to manufacture component 14 include titanium 6-4, titanium 6-2-4-2 and titanium 17. However, it should be understood that other conventional titanium-based alloys may be used to manufacture component 14. In the illustrative embodiment, workpiece 14 may comprise a component of a gas turbine engine, such as a fan or compressor case or an exhaust duct. Furthermore, it should be understood that component 14 may correspond to newly produced hardware or alternatively hardware which has accumulated service time during operation of a gas turbine engine. In the first instance, alpha case may be present on selected portions of surface 12, or over the entire surface 12, due to the heat treat process used to manufacture component 14. In the second instance, alpha case may be present on at least a portion of surface 12 due to a local overtemperature condition during field operation of the corresponding gas turbine engine. In either event, it is desirable to detect the presence of alpha case and then remove it, since the portions of surface 12 having alpha case present are very brittle as compared to the remainder of surface 12 which may lead to the initiation of a crack in the areas having alpha case if the alpha case is not detected and removed. Such a crack initiation may then propagate through a portion of component 14 and may ultimately lead to the failure of component 14 during operation of the corresponding gas turbine engine.

Component 14 is mounted to a fixture 16 having a first portion 18 secured to a stationary surface 20 and a second portion 22 attached to the first portion 18 and operable for rotating component 14 in either a clockwise or counterclockwise direction about a centerline axis 24 of component 14. Fixture 16 is also operable for translating component 14 in first or second directions 26 and 28, respectively, with directions 26 and 28 being substantially parallel to the centerline axis 24 of component 14.

System 10 includes a source 30 of infrared radiation which is mounted to a fixture 32 so as to position the source 30 spatially apart from the surface 12 of component 14. The source 30 may comprise a conventional electric heater and is a controlled source of infrared radiation since source 30 is coupled via cable 34 to a power supply 36 which is operable for controlling the temperature of heater, or source 30. Source 30 produces infrared radiation 38 which is directed onto, and reflected off of a selected portion of the surface 12 of component 14. Conventional cleaning or degreasing procedures may be applied to surface 12 if required prior to directing the infrared radiation onto surface 12, depending upon the particular condition of surface 12. The size of the selected portion of surface 12 irradiated by the infrared radiation 38 depends on the distance of source 30 from surface 12, as well as the size of an aperture (not shown) in source 30 which is operable for emitting the infrared radiation 38 from within source 30. The particular desired size of the selected portion of surface 12 to be irradiated depends upon the particular application, i.e. the overall size and geometry of the workpiece or component to be inspected. The infrared radiation 38 forms an angle of incidence 40 and an angle of reflection 42 with respect to surface 12, with angles 40 and 42 being substantially equal to one another. System 10 further includes a detector 44 mounted to a fixture 46. Detector 44 senses or detects the infrared radiation 38 reflected off of the selected portion of the surface 12 of component 14. Detector 44 preferably comprises an infrared radiometer, such as a Model 760 or a Model 740 scanning infrared radiometer manufactured by Inframetrics of Billerica, Mass. Alternatively, detector 44 may comprise an infrared camera, having a focal plane array such as a ThermaCam or an InfraCam manufactured by Inframetrics. As a further alternative, detector 44 may comprise other conventional radiometers such as a spot infrared radiometer and other infrared cameras, such as a scanning infrared camera. The inventors have determined, with the aid of a spectrometer (which is not used to practice the method of the present invention and is not shown in FIG. 1), that the intensity of infrared radiation reflected off of an alpha case area of a surface of a workpiece made of a titanium-based alloy, comprising titanium 6-4, has a lower intensity than infrared radiation similarly reflected off of a surface made of titanium 6-4 which does not contain alpha case, over a wavelength band ranging from about 3 microns to about 5 microns. This fact is illustrated in FIG. 2 where the reflectance of a non-alpha-case titanium 6-4 surface is illustrated, as a function of wavelength by curve 48. Similarly, the reflectance of an alpha case portion of a surface of a titanium 6-4 workpiece is illustrated as a function of wavelength by curve 50. As shown in FIG. 2, curve 50 is consistently lower than curve 48 in a wavelength band 51 ranging from about 3 microns to about 5 microns. The difference between curves 48 and 50 is about 3-5% over a substantial portion of the wavelength band ranging from about 3 microns to about 5 microns. Based on this difference in reflectance characteristics, detector 44 is preferably operated in a wavelength band ranging from about 3 microns to about 5 microns so as to enhance the signal to noise ratio. Utilizing the method of the present invention, the inventors have observed the same trend shown in FIG. 2, i.e. a reduction in intensity due to the presence of alpha case, on a gas turbine engine component made of titanium 6-2-4-2 which had undergone heat treatment at a time and temperature known to cause alpha case. Based on the inherent properties of titanium and all titanium-based alloys, the inventors expect the same trend to exist, i.e. a reduction in intensity due to the presence of alpha case, for titanium and all titanium-based alloys. Output signals from detector 44, preferably comprising a scanning infrared radiometer, are supplied to a radiometer control 52 via a data link 54. Radiometer control 52 may be used to adjust the focus and contrast of the detector 44. Depending upon the particular selection of equipment for detector 44, radiometer control 52 and detector 44 may comprise an integral unit. Radiometer control 52 is coupled to a digitizer 56 via data link 58. The output of the radiometer control 52 may also be supplied via link 58 and another data link 60 to a recorder 62 for recording analog data of the infrared radiation reflected off of the selected portion of surface 12 of component 14. The digitizer 56 is coupled, or connected to an output display 64 and a digital computer 66 via data links 68 and 70, respectively. When detector 44 comprises a scanning infrared radiometer or an infrared camera, digitizer 56 comprises an image digitizer and recorder 62 may comprise a videocassette recorder (VCR). Accordingly, an image of the infrared radiation reflected off of the selected portion of the surface 12 of component 14, which may be created by detector 44 and digitizer 56 may be viewed on-line on output display 64 and/or processed by digital computer 66, which may be used to generate a graph of intensity of the reflected infrared radiation within the image versus distance along surface 12 within the image. This graph may then be printed by a printer 72 coupled to computer 66 via a data link 74. It should be noted than when detector 44 comprises a spot infrared radiometer a single value of the intensity of the reflected infrared radiation is produced, but an image of the reflected infrared radiation is not produced. In this instance, digitizer 56 does not comprise an image digitizer and output display 64 may alternatively comprise a digital display unit operable for displaying the value of intensity of the reflected infrared radiation. Additionally, in this instance recorder 62 may comprise a variety of other recorders such as a strip chart recorder or a reel-to-reel tape recorder, rather than a videocassette recorder. The use of either a scanning infrared radiometer or an infrared camera are considered preferable, with the scanning infrared radiometer being most preferable, since the use of scanning infrared radiometers or infrared cameras permits the creation of an image of the reflected infrared radiation, which in turn permits an evaluation of the variation of the intensity within the image and an assessment of the variation of the depth of alpha case which may be present. In contrast, the use of a spot infrared radiometer provides a single average intensity value. It is important that the source 30 of the infrared radiation and the detector 44 of the infrared radiation are fixtured, with the illustrated individual fixtures 32 and 46, respectively, or alternatively with a single fixture (not shown) rigidly interconnecting source 30 and detector 44 so that the detector 44 is substantially aligned with the optical path of the infrared radiation 38 reflected off of the selected portion of surface 12 of component 14. This is important because the inventors have determined that the scatter of the reflected radiation is more pronounced for a surface having alpha case than for a non-alpha-case surface, i.e. less radiation is reflected at the specular angle when alpha case is present than the corresponding reflection for an alpha-case surface. Accordingly, the previously discussed difference in reflectance exhibited between alpha case and non-alpha-case surfaces is more pronounced, or larger, at the specular angle which corresponds to the angle of reflection 42. The operator of system 10 may detect the presence of alpha case on surface 12 by comparing the intensity of the reflected infrared radiation from the selected portion of surface 12 of component 14 to a predetermined intensity known to be indicative of the absence of alpha case. As indicated in FIG. 2, the presence of alpha case will result in a reduction in intensity relative to the intensity exhibited by infrared radiation reflected off of a non-alpha-case surface. The operator of system 10 may make this comparison in a variety of ways. One way which this may be accomplished, when detector 44 comprises a spot infrared radiometer, is to compare the intensity of the reflected infrared radiation displayed on output display 64, which may comprise a digital display unit, to a predetermined intensity known to be indicative of the absence of alpha case. Another way this may be accomplished, when detector 44 comprises either a scanning infrared radiometer or an infrared camera, is to compare the intensity, or brightness, of the reflected infrared radiation within the image displayed on video display monitor 64 to a photograph of an inspection standard image known to be indicative of an absence of alpha case. Alternatively, and more preferably when detector 44 comprises either a scanning infrared radiometer or an infrared camera, this comparison may be made by comparing the peak values of a graph of the image of the reflected infrared radiation from surface 12 produced by printer 72, or by a digital display of the intensity of the reflected infrared radiation within the image created, to a predetermined value of intensity known to be indicative of the absence of alpha case. It should be understood, that with any of the aforementioned alternative methods of comparing intensity, the particular intensity known to be indicative of the absence of alpha case corresponds to the same material, i.e. either the same titanium-based alloy or titanium, as the material used to manufacture surface 12 of component 14.

In operation an initial selected portion of the surface 12 of component 14 is inspected for the presence of alpha case in the previously discussed manner. Component 14 may then be subsequently rotated and/or translated by fixture 16 and a conventional source of motive power (not shown) associated with fixture 16, so that the entirety of surface 12 may be inspected for the presence of alpha case. In the illustrative embodiment, surface 12 comprises a generally cylindrical surface of a gas turbine engine component such as a fan or compressor case or exhaust duct. However, the method of the present invention may be utilized to inspect other workpieces and components having a wide variety of geometrical shapes. In such instances, it should be understood that fixture 16 may include additional degrees of freedom, as required, so that the titanium surfaces of interest may be completely and fully inspected for the presence of alpha case.

FIG. 3 is a combined schematic and block diagram illustrating an inspection system, indicated generally at 100, which may be used to practice the method of the present invention according to a second, preferred embodiment. System 100 is identical to system 10 with the following exceptions. In the preferred embodiment corresponding to system 100, the creation of an image of the infrared radiation reflected off of surface 12 is required since the method of the present invention according to this embodiment utilizes not only the intensity of the reflected infrared radiation but the clarity of the image of the reflected infrared radiation to nondestructively detect and quantify the presence of any alpha case on surface 12. Accordingly, in this embodiment digitizer 56, recorder 62 and output display 64 preferably comprise an image digitizer, a video display monitor and a videocassette recorder, respectively. Additionally, detector 44 may comprise either a scanning infrared radiometer or an infrared camera but may not comprise a spot infrared radiometer. Additionally, system 100 includes a target housing 102 disposed in the optical path of the infrared radiation 38 emitted from the source 30 and positioned between source 30 and the surface 12 of component 14. The target housing 102 includes a generally central aperture 104, which may comprise a variety of structured shapes such as the shape as shown in FIG. 4, which extends through housing 102. System 100 further includes a target 106 which is attached to, and may be integral with, housing 102. Target 106 comprises a plurality of bars 108, shown in FIG. 4, which are spaced apart from one another and extend across aperture 104. In the illustrative embodiment, bars 108 have a generally rectangular shape and are unequally spaced from one another. Additionally, in the illustrative embodiment shown in FIG. 4, bars 108 are substantially parallel to one another and are generally vertically extending. However, bars 108 may alternatively be equally spaced, and extend in other directions. Furthermore, bars 108 may either have equal thicknesses or different thicknesses. The spaced bars 108 shown in FIG. 4 form a plurality of generally rectangular spaces 110 formed between adjacent pairs of bars 108. The infrared radiation 38 emitted from the source 30 may pass through the generally rectangular spaces 110 but is blocked in areas corresponding to bars 108 and a portion 112 of housing 102 which surrounds aperture 104. Accordingly, a predetermined pattern corresponding to a plurality of generally rectangular and spaced shapes is formed within the image created of the infrared radiation 38 reflected off of the surface 12 of component 14. However, the predetermined pattern may comprise a wide variety of other shapes which may be created by varying the shape of aperture 104 and the configuration of target 106 relative to the illustrative embodiment shown in FIG. 4. The particular choice of the shapes comprising the predetermined pattern is relatively unimportant and may be tailored to the size and configuration of the surface to be inspected. In this embodiment, the operator of system 100 may detect the presence of alpha case by comparing the intensity of the reflected infrared radiation from a selected portion of surface 12 of component 14, within the image created of the reflected infrared radiation, to the predetermined intensity known to be indicative of the absence of alpha case, as described previously with respect to system 10, and by comparing the clarity of the predetermined pattern within the image of the reflected infrared radiation to the clarity of the same predetermined pattern within an inspection standard image created from infrared radiation reflected off of the corresponding inspection standard, non-alpha-case titanium or titanium-based alloy surface, which may be presented in the form of a photograph. The inventors have determined that the additional step of comparing the clarity of the predetermined pattern within the image of the reflected infrared radiation from the selected portion of surface 12 significantly enhances the ability of the operator to detect the presence of alpha case, due to the previously discussed increased scatter characteristic of alpha case as compared to clean, or non-alpha-case titanium or titanium-based alloy surfaces. The presence of alpha case causes the predetermined pattern within the image of the reflected infrared radiation to appear blurred, or less clear than a corresponding image created from reflected infrared radiation from a non-alpha-case titanium or titanium-based alloy surface. System 100 and the corresponding embodiment of the method of the present invention are otherwise the same as that discussed previously with respect to system 10.

The following example is provided to demonstrate some of the benefits which may be achieved by following the teachings of this invention.

EXAMPLE

The method of the present invention, corresponding to the preferred embodiment associated with system 100, was separately applied to three coupons made of titanium 6-4. Each of the three coupons were subjected to the standard heat treatment and chemical cleaning conventionally used in the manufacture of certain titanium 6-4 gas turbine engine components. A portion of each of the coupons was destructively inspected for the presence of alpha case. Based on photo-micrographs of this destructive testing, a first one of the coupons was verified to be free of alpha case, while the second coupon contained alpha case varying from 1 to 3 mils in depth (which was characterized as "moderate" alpha case) and the third coupon contained alpha case in excess of 5 mils in depth (which was characterized as "heavy" alpha case). The images created from each of the coupons were observed on a video display monitor and transmitted to a digital computer. The images created from the first, second and third coupons are shown in FIGS. 5A, 5B and 5C, respectively. Additionally, for each of the images created from the three coupons, a graph was generated of image intensity versus distance within the image using the digital computer. This data is presented in FIG. 6 and was taken from a portion of each of the three images corresponding to that enclosed by the generally rectangular boxes shown in solid lines in FIGS. 5A-5C. In this example, the image shown in FIG. 5A, corresponding to the coupon having no alpha case, may be considered the inspection standard image. Comparison of FIGS. 5B and 5C to FIG. 5A shows that the predetermined pattern, or plurality of spaced, generally rectangular shapes, within FIGS. 5B and 5C are blurred, or are less clear, relative to the corresponding pattern within FIG. 5A. Additionally, as shown in FIG. 6, the graphs corresponding to both moderate and heavy alpha case show a reduced intensity relative to the graph corresponding to no alpha case. It is noted that the variation in peaks of the graph corresponding to moderate alpha case was due to the variance in the thickness of the alpha case present in the corresponding test coupon. Accordingly, using FIGS. 5A-5C and FIG. 6 the presence of alpha case in the second and third test coupons was confirmed.

Any of the previously discussed embodiments of the method of the present invention may be used to not only detect the presence of alpha case, but to quantify the thickness of any alpha case which is present. This may be accomplished by using carefully controlled test coupons and data such as that shown in FIG. 6, where an amplitude of an intensity graph, such as an amplitude 114 (corresponding in this case to an amplitude of a portion of the moderate alpha case graph) may be correlated to a known depth of alpha case. This correlation may also be accomplished utilizing the alternative, previously discussed methods of displaying the intensity of the reflected infrared radiation, in lieu of a graph. In this manner, a table may be constructed of intensity of the reflected infrared radiation versus depth of alpha case. As noted by comparing the moderate alpha case and heavy alpha case graphs in FIG. 6, a reduction in intensity (shown in FIG. 6 as a reduction in amplitude) indicates an increase in the thickness of the alpha case.

The method of the present invention provides a reliable, cost effective and environmentally safe method for detecting the presence of alpha case on the surface of titanium and titanium-based alloy components such as those used in gas turbine engines. The method of the present invention may be advantageously utilized after completion of conventional heat treat and chemical cleaning processes during the manufacture of newly produced hardware. However, the method of the present invention may also be used in a variety of other circumstances and no unusual or special pre-inspection preparation or post-inspection cleaning of the surface to be inspected is expected to be required and the method of the present invention avoids the use of the potentially environmentally offensive chemicals of prior conventional methods of detecting alpha case. Additionally, the method of the present invention avoids the difficulties in component temperature control associated with prior conventional infrared radiation methods of detecting surface or subsurface defects or flaws.

While the foregoing description has set forth the preferred embodiments of the invention in particular detail, it must be understood that numerous modifications, substitutions and changes can be undertaken without departing from the true spirit and scope of the present invention as defined by the ensuing claims. For instance, although the method of the present invention has been illustrated in conjunction with the detection of alpha case on titanium or titanium-based alloy surfaces, the principles of the method of the present invention may be extended to detect the presence of similar surface conditions on other metals or the absence of various coatings on metallic surfaces. The invention is therefore not limited to specific preferred embodiments as described but is only limited as defined by the following claims. 

What is claimed is:
 1. A method for nondestructive/noncontact detection and quantification of alpha case on a surface of a workpiece made of a material selected from a group consisting of titanium and titanium-based alloys, said method comprising the steps of:reflecting infrared radiation off of a selected portion of the surface of the workpiece; sensing the reflected infrared radiation from the selected portion of the surface of the workpiece with a detector and creating an image of intensity of the reflected infrared radiation sensed by the detector versus distance along the selected portion of the surface; and detecting the presence of any alpha case on the selected portion of the surface of the workpiece, wherein said step of detecting comprises the step of comparing the image of intensity of the reflected infrared radiation sensed by the detector versus distance along the selected portion of the surface of the workpiece to a predetermined image of intensity of the reflected infrared radiation versus distance along the selected portion of the surface known to be indicative of the absence of alpha case, wherein the presence of alpha case will cause a reduction in intensity of the reflected infrared radiation along the selected portion of the surface of the workpiece relative to that of the predetermined intensity.
 2. The method as recited in claim 1, wherein said step of sensing comprises the step of:operating the detector in a predetermined wavelength band.
 3. The method as recited in claim 2, wherein the predetermined wavelength band ranges from about 3 microns to about 5 microns.
 4. The method as recited in claim 1, further comprising the step of:quantifying the thickness of any alpha case detected during said detecting step.
 5. The method as recited in claim 4, wherein said step of quantifying comprises the step of:correlating a magnitude of the intensity of the reflected infrared radiation from the selected portion of the surface of the workpiece to a thickness of alpha case.
 6. The method as recited in claim 1, wherein the detector is selected from a group consisting of a scanning infrared radiometer, a spot infrared radiometer, and an infrared camera.
 7. A method for nondestructive/noncontact detection and quantification of alpha case on a surface of a workpiece made of a material selected from a group consisting of titanium and titanium-based alloys, said method comprising the steps of:reflecting infrared radiation off of a selected portion of the surface of the workpiece; sensing the reflected infrared radiation from the selected portion of the surface of the workpiece with a detector; detecting the presence of any alpha case on the selected portion of the surface of the workpiece by comparing the intensity of the reflected infrared radiation from the selected portion of the surface of the workpiece to a predetermined intensity known to be indicative of the absence of alpha case, wherein the presence of alpha case will cause a reduction in intensity of the reflected infrared radiation from the selected portion of the surface of the workpiece relative to that of the predetermined intensity; said step of reflecting infrared radiation off of the selected portion of the surface of the workpiece includes the steps of; positioning a controlled source of infrared radiation spaced apart from the surface of the workpiece, directing the infrared radiation emitted by the source onto the selected portion of the surface of the workpiece, creating an image from the reflected infrared radiation sensed by the detector, disposing a target between the source of the infrared radiation and the selected portion of the surface of the workpiece so as to create a predetermined pattern within the image of the reflected infrared radiation from the selected portion; and said step of detecting further comprises the step of comparing the intensity of the reflected infrared radiation within the image of the reflected infrared radiation to the predetermined intensity and the clarity of the predetermined pattern within the image of the reflected infrared radiation from the selected portion of the surface of the workpiece to the clarity of the predetermined pattern within an inspection standard image known to be indicative of an absence of alpha case.
 8. The method as recited in claim 7, wherein said step of comparing the intensity of the reflected infrared radiation from the selected portion of the surface of the workpiece to a predetermined intensity comprises the steps of:generating a graph of intensity of the image of the reflected infrared radiation from the selected portion of the surface of the workpiece versus distance along the workpiece within the image; comparing peak values of intensity shown in the graph to the predetermined intensity known to be indicative of an absence of alpha-case.
 9. The method as recited in claim 7, wherein said step of comparing the clarity of the predetermined pattern within the image of the reflected infrared radiation comprises the steps of:displaying the image of the reflected infrared radiation from the selected portion of the surface of the workpiece on a video display monitor; comparing the clarity of the predetermined pattern within the image of the reflected infrared radiation displayed on the video display monitor to the clarity of the predetermined pattern within the inspection standard image.
 10. The method as recited in claim 7, further comprising the step of: fixturing the source of the infrared radiation and the detector of the infrared radiation so that the detector is substantially aligned with the optical path of the infrared radiation reflected off of the selected portion of the surface of the workpiece.
 11. The method as recited in claim 7, wherein the predetermined pattern comprises a plurality of spaced, generally rectangular shapes. 